A higher viscosity fluid dispensing apparatus is provided having a reservoir chamber and a pump head positioned adjacent to an end of the reservoir chamber. The pump head includes a pump body having a pump cavity formed therein, a first one-way valve between the reservoir chamber and the pump cavity, a piston slidably engaged with the pump cavity and having a pump outlet in fluid communication with the pump cavity, and a second one-way valve between the pump outlet and the first one-way valve. The first one-way valve and second one-way valve cooperate to draw a higher viscosity fluid from the reservoir chamber into the pump cavity and expel the fluid out of the pump cavity through the pump outlet.
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18. A method of constructing a higher viscosity fluid dispensing pump comprising the steps of:
molding a reservoir chamber from a polymer material, the reservoir chamber comprising a first end, a second end, and a wall formed along a length thereof;
molding a pump head from a polymer material, the pump head comprising a pump body including a pump cavity formed therein, a first handle portion, a bridge portion, and a second handle portion;
providing a first one-way valve positioned between the reservoir chamber and the pump cavity of the pump body;
providing a piston including a pump passage formed therethrough; and
providing a second one-way valve mounted on the piston between an outlet of the pump and the first one-way valve and in fluid communication with the pump passage of the piston;
slidably engaging the piston with the pump cavity of the pump body such that the piston is located between the second handle portion and the first handle portion.
1. A higher viscosity fluid dispensing pump comprising:
a pump head including:
a pump body, the pump body including a pump cavity formed therein, the pump cavity in fluid communication with a reservoir chamber;
a first one-way valve positioned between the reservoir chamber and the pump cavity of the pump body configured to allow passage of a higher viscosity fluid only from the reservoir chamber into the pump cavity;
a piston slidably engaged with the pump cavity, the piston including a pump passage formed through the piston, the pump passage in fluid communication with the pump cavity; and
a second one-way valve mounted on the piston between an outlet of the pump and the first one-way valve and in fluid communication with the pump passage of the piston, the second one-way valve configured to allow passage of a higher viscosity fluid only in a direction from the pump cavity to the outlet of the pump through the piston;
wherein the first one-way valve and second one-way valve cooperate to draw a higher viscosity fluid into the pump cavity, through the pump passage of the piston and out of the pump outlet.
17. A high-viscosity fluid dispensing pump comprising:
a molded polymer reservoir chamber having a first end, a second end distal from the first end, and a wall extending along a length of the reservoir chamber;
a molded polymer pump head, non-removably and/or removably positioned adjacent the first end of the reservoir chamber; the pump head including:
a pump body, the pump body including a pump cavity formed therein, the pump cavity in fluid communication with the reservoir chamber;
a first one-way valve positioned between the reservoir chamber and the pump cavity of the pump body configured to allow passage of a higher viscosity fluid only from the reservoir chamber into the pump cavity;
a piston slidably engaged with the pump cavity, the piston including a pump outlet formed in the piston, the pump outlet in fluid communication with the pump cavity; and
a spring positioned at least partially around the pump cavity such that the spring resists urging of the piston to slidably engage with the pump cavity in one direction, and aids slidable engagement of the piston with the pump cavity in the opposite direction; the spring also reinforces the pump cavity, thus enabling the polymer pump cavity to withstand higher internal pressures;
a second one-way valve positioned between the pump outlet and the first one-way valve, the second one-way valve configured to allow passage of a higher viscosity fluid only in a direction from the pump cavity to the pump outlet;
a single piece molded handle comprising:
a first handle portion attached adjacent the first end of the reservoir chamber and extending substantially downward from the dispenser;
a second handle portion located adjacent the end of the piston and extending substantially downward from the dispenser; and
a bridge portion connecting the first handle portion to the second handle portion;
wherein the reservoir chamber is non-removably secured to the pump head to discourage reservoir chamber replacement and/or refilling, and re-use of the dispenser after all of the higher viscosity fluid within the reservoir chamber is expelled from the dispenser;
wherein the reservoir chamber is removably secured to the pump head to allow reservoir chamber replacement and/or refilling, and re-use of the dispenser.
2. The higher viscosity fluid dispensing pump of
3. The higher viscosity fluid dispensing pump of
4. The higher viscosity fluid dispensing pump of
5. The higher viscosity fluid dispensing pump of
6. The higher viscosity fluid dispensing pump of
7. The higher viscosity fluid dispensing pump of
a first handle portion attached adjacent the first end of the reservoir chamber and extending substantially downward from the dispenser, and
a second handle portion located adjacent the end of the piston and extending substantially downward from the dispenser;
wherein when a user squeezes the second handle portion towards the first handle portion, the second handle portion urges the piston to slidably engage with the pump cavity to substantially force higher viscosity fluid within the pump cavity out of the pump outlet.
8. The higher viscosity fluid dispensing pump of
9. The higher viscosity fluid dispensing pump of
10. The higher viscosity fluid dispensing pump of
11. The higher viscosity fluid dispensing pump of
12. The higher viscosity fluid dispensing pump of
13. The higher viscosity fluid dispensing pump of
14. The higher viscosity fluid dispensing pump of
15. The higher viscosity fluid dispensing pump of
16. The higher viscosity fluid dispensing pump of
20. The method of
21. The method of
23. The method of
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This application claims priority to U.S. patent application Ser. No. 14/756,847 to Daniel Mark Sorg for a Grease gun and cartridge unit, which was filed on Oct. 21, 2015 and claims priority to U.S. Provisional Patent Application Ser. No. 62/122,443 for a Grease gun and cartridge unit, which was filed on Oct. 21, 2014, the contents of which are incorporated herein by reference in their entireties.
This disclosure relates to the field of fluid dispensers. More particularly, this disclosure relates to a non-refillable or refillable, preferably higher viscosity, fluid dispenser, and could also be used in various other applications to dispense other fluids.
Grease guns have typically been primarily constructed of expensive, relatively heavy metal parts such as a metal barrel into which a grease cartridge could be placed, a metal grease pressurizing compression spring and piston, a metal spring compressing (cocking) rod, a metal grease pump head and metal pump handles. Typically, the metal pump head incorporates a piston-type pumping mechanism, a single check valve, and an air bleed port which may aid in evacuating the trapped air introduced during the loading process. The single check valve configuration does not allow for the expelling of the trapped air without the use of the air bleed port. The cartridge loading operation for such structures, particularly where the pressurizing spring compressing (cocking) rod must be retracted and held in place while the cartridge is positioned in the barrel, can be a difficult and messy operation for many users. Also, such structures do not allow the operator to view the contents of the barrel, or the legends on the cartridge wall which denote, e.g., manufacturer, brand, type, lot number, and expiration date, the amount of grease (consumed and remaining) in the cartridge, and the condition of the grease, e.g., whether separation (lubricant from thickener) has occurred in the cartridge. Further the present invention, in a preferred embodiment, may be constructed so as to prevent removal of a cartridge and its replacement with a cartridge having the wrong and deleterious type of grease for some highly sensitive applications.
Typical of such prior art grease gun structures are shown in U.S. Pat. Nos. 1,697,217; 1,714,214; 4,601,412; 3,187,959; 1,633,356; 1,812,643; 3,393,840; 3,341,084; 2,284,533, the disclosures of which are hereby incorporated herein by reference in their entireties.
A higher viscosity fluid dispenser, in one preferred embodiment, is formed principally of transparent plastic material, wherein the reservoir chamber stands alone without a surrounding supporting metal barrel, wherein the reservoir chamber has an air passage which may be one-way valved, and may have a closed distal end. The reservoir chamber may be non-removably or removably fixed to the inlet portion of a pump head, wherein the pump head including the pump handles may be comprised of a single plastic molding, wherein the reservoir chamber has no pressurizing compression spring, no piston, and no spring compressing (cocking) rod, wherein valving structures in the pump head are preferably of molded plastic material, whereby the components are lightweight, and easy to manufacture and use, wherein said valving structures are positioned in the pump head to allow self-priming of the pump, and wherein ambient air pressure is utilized to load the pump head with fluid.
The reason for such construction wherein the reservoir chamber is non-refillable and non-removably fixed to the pump body is to inhibit refilling and prevent non-destructive removal of the reservoir chamber and inadvertent reservoir chamber refilling or replacement of the reservoir chamber with a reservoir chamber containing a fluid which is not of the correct composition and which is, in fact, detrimental to the structure in which the fluid is to be applied. This incompatibility problem can still remain even though the mistake is discovered before the application process is started anew with the correct fluid, because the incorrect fluid may already have been pumped into the interstices of the pump head and the outlet conduit. Such sensitive structures are commonly found in the aeronautics and space industries, the medical field, the electronics industry, the food industry, and many other areas.
In a first aspect, a non-refillable single-use, or refillable fluid dispenser includes: a reservoir chamber having a first end, a second end distal from the first end, and a wall extending along a length of the reservoir chamber and a pump head non-removably or removably positioned adjacent to the first end of the reservoir chamber, the pump head including: a pump body, the pump body including a pump cavity formed therein, the pump cavity in fluid communication with the reservoir chamber; a first one-way fluid valve positioned between the reservoir chamber and the pump cavity of the pump body configured to allow passage of fluid only from the reservoir chamber into the pump cavity; a piston slidably engaged with the pump cavity, the piston including a pump outlet formed in the piston, the pump outlet in fluid communication with the pump cavity; and a second one-way fluid valve positioned between the pump outlet and the first one-way fluid valve, the second one-way fluid valve configured to allow passage of fluid only in a direction from the pump cavity to the pump outlet; wherein the first one-way fluid valve and second one-way fluid valve cooperate to draw fluid from the reservoir chamber into the pump cavity and expel the fluid out of the pump cavity through the pump outlet; and wherein the reservoir chamber may be non-removably positioned adjacent the pump head to discourage refilling of the dispenser, which may be desirable in applications where cross-contamination of fluids are of primary concern; and wherein the reservoir chamber may also be removably positioned in fluid communication with the pump head, to allow for reservoir chamber refilling or replacement, which may be desirable in applications where cross-contamination of fluids are of less concern.
In one embodiment, the fluid dispenser further includes a wiper disc slidably engaged within the reservoir chamber, the wiper disc, which is located distally in the reservoir chamber, is in direct communication with fluid stored within the reservoir chamber, and is configured to form a slidable seal between the wiper disc and the wall of the reservoir chamber, wherein the wiper disc moves proximally in the reservoir chamber as fluid is drawn from the reservoir chamber into the pump cavity.
In another embodiment, the fluid dispenser further includes a one-way air valve located adjacent to the second end of the reservoir chamber and is in fluid communication with an interior of the reservoir chamber, wherein the one-way air valve allows ambient air to enter the reservoir chamber, between the wiper disc and second end of the reservoir chamber, as the wiper disc moves towards the first end of the reservoir chamber.
In yet another embodiment, the fluid dispensing pump further includes: a first handle portion adjacent to the first end of the reservoir chamber and extending substantially downward from the pump head, and a second handle portion adjacent to the end of the piston and extending substantially downward from the pump head; wherein when a user squeezes the second handle portion towards the first handle portion, the second handle portion urges the piston to slidably engage with the pump cavity to substantially force fluid within the pump cavity out of the pump outlet.
In one embodiment, the fluid dispenser further includes a bridge portion connecting the top of the first handle portion to the top of the second handle portion. In another embodiment, the first handle portion, bridge portion, and second handle portion are formed as a single piece. In yet another embodiment, the pump body is also formed as part of the first and second handle portions and bridge portions such that the pump body, first handle portion, second handle portion, and bridge portion are formed as a single piece.
In one embodiment, the fluid dispenser further includes a first crease formed between the first handle portion and the bridge portion and a second crease formed between the second handle portion and the bridge portion, wherein the first and second handle portions hinge about the first and second creases. In another embodiment, the reservoir chamber and pump head are formed from a polymer. In yet another embodiment, the reservoir chamber and pump head are formed as a single piece of molded polymer.
In one embodiment, the reservoir chamber is attached to the pump head at a collar formed in the pump body such that the collar may prevent the reservoir chamber from being non-destructively removed from the pump head. In another embodiment, the collar formed in the pump body, may allow for the removal of the reservoir chamber from the pump head.
In another embodiment, the fluid dispensing pump further includes a spring positioned between the first end of the reservoir chamber and the end of the piston such that the spring resists urging of the piston to slidably engage with the pump cavity.
In yet another embodiment, the fluid dispensing pump further includes a one-way air valve located adjacent to the second end of the reservoir chamber and in fluid communication with an interior of the reservoir chamber, wherein the one-way air valve allows air pressure, ambient or pressurized, to enter the reservoir chamber between the wiper disc and second end of the reservoir chamber as the wiper disc moves towards the first end of the reservoir chamber.
In a second aspect, a fluid dispenser is provided including: a molded polymer reservoir chamber having a first end, a second end distal from the first end, and a wall extending along a length of the reservoir chamber; a molded polymer pump head non-removably or removably positioned adjacent the first end of the reservoir chamber, the pump head including: a pump body, the pump body including a pump cavity formed therein, the pump cavity in fluid communication with the reservoir chamber; a first one-way fluid valve positioned between the reservoir chamber and the pump cavity of the pump body configured to allow passage of fluid only from the reservoir chamber into the pump cavity; a piston slidably engaged with the pump cavity, the piston including a pump outlet formed therein, the pump outlet in fluid communication with the pump cavity; and a second one-way fluid valve positioned between the pump outlet and the first one-way fluid valve, the second one-way fluid valve configured to allow passage of fluid only in a direction from the pump cavity to the pump outlet; a single piece molded handle comprising: a first handle portion attached adjacent the first end of the reservoir chamber and extending substantially downward; a second handle portion adjacent the end of the piston and extending substantially downward; and a bridge portion connecting the first handle portion to the second handle portion; wherein the reservoir chamber is non-removably fixed to the pump head to discourage re-use of the gun after all of the fluid within the reservoir chamber is expelled; wherein the reservoir chamber may also be removably positioned in fluid communication with the pump head, to allow for reservoir chamber refilling or replacement, which may be desirable in applications where cross-contamination of fluids are of less concern.
In a third aspect, a method of constructing a fluid dispenser is provided including the steps of: molding a reservoir chamber from a polymer material, the reservoir chamber comprising a first end, a second end, and a wall formed along a length thereof; molding a pump head from a polymer material, the pump head comprising a first handle portion, a bridge portion, and a second handle portion, and a pump cavity formed therein; providing a piston including a pump outlet formed therethrough; and the piston slidably engaged with the pump cavity of the pump body such that the piston is adjacent the second handle portion and the first handle portion.
In one embodiment, the pump head is molded as a single piece. In another embodiment, the method further includes the steps of molding a crease between the first handle portion and the bridge portion and the second handle portion and the bridge portion such that the pump head may be formed as a single elongated piece and the second handle portion may be subsequently folded over the piston to retain the piston adjacent the second handle portion and the first handle portion. In one embodiment, the reservoir chamber and pump head are molded as a single piece. In another embodiment, the reservoir chamber is non-removably positioned to the pump body. In yet another embodiment, the reservoir chamber may be removably positioned to the pump body.
Further features, aspects, and advantages of the present disclosure will become better understood by reference to the following detailed description, appended claims, and accompanying figures, wherein elements are not to scale so as to more clearly show the details, wherein like reference numbers indicate like elements throughout the several views, and wherein:
Various terms used herein are intended to have particular meanings. Some of these terms are defined below for the purpose of clarity. The definitions given below are meant to cover all forms of the words being defined (e.g., singular, plural, present tense, past tense). If the definition of any term below diverges from the commonly understood and/or dictionary definition of such term, the definitions below control.
A fluid dispensing pump is provided that includes a reservoir and a pump head. The reservoir may be fixed to the pump head such that the reservoir is non-destructively removable, thereby making the fluid dispenser suitable for “single use or disposable” applications. The fluid dispensing pump is formed of relatively few components thereby further easing the process of manufacturing the fluid dispenser and further making the dispenser suitable for single use or throwaway applications. Further, the fluid dispenser of the present disclosure may be packaged as a pre-filled assembly, thereby eliminating a need to assemble, fill, or refill the dispenser.
In a preferred embodiment, as shown in
One preferred embodiment may not incorporate a closed reservoir chamber end 28 (
In one embodiment, as shown in
In one embodiment of the fluid dispenser construction, reservoir chamber 20 and at least a portion of pump head 21 may be constructed as a single piece (
As shown in
As shown in
As shown in
As shown in
In another preferred embodiment, as shown in
As shown in
As shown in
As shown in
In
The fluid dispenser of the present disclosure is advantageously configured to be substantially in-line, such that components are aligned along a central axis, thereby allowing a user to easily manipulate the fluid dispenser in confined operating environments. The valving configuration of pump head 21 (
The foregoing description of preferred embodiments of the present disclosure has been presented for purposes of illustration and description. The described preferred embodiments are not intended to be exhaustive or to limit the scope of the disclosure to the precise form(s) disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiments are chosen and described in an effort to provide the best illustrations of the principles of the disclosure and its practical application, and to thereby enable one of ordinary skill in the art to utilize the concepts revealed in the disclosure in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the disclosure as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
1349994, | |||
1368840, | |||
1718985, | |||
1833528, | |||
1905913, | |||
1926398, | |||
1945813, | |||
2205604, | |||
2275108, | |||
2759640, | |||
2915226, | |||
2978151, | |||
3246802, | |||
3338478, | |||
3344084, | |||
3393840, | |||
3653555, | |||
4601412, | Nov 07 1983 | REXNORD INC | Polymeric grease gun |
4664298, | May 01 1985 | STEWART-WARNER ALEMITE LICENSCO INC | Dual mode grease gun |
4775302, | Dec 20 1984 | Lincoln Industrial Corporation | Hand-held vacuum and pressure pump |
5139178, | Nov 11 1987 | Dow Corning S.A. | Sealant cartridge under pressure during storage |
6068164, | Mar 01 1996 | Hand grease gun with lever-operated piston pump and tubular grease supply reservoir | |
6135327, | Oct 01 1998 | Lincoln Industrial Corporation | Battery operated grease gun |
6467579, | Mar 22 1997 | MATO Maschinen-und Metallwarenfabrik Curt Matthaei GmbH & Co. KG | Press for compressing lubricating grease and the cartridges used therefor |
6834781, | May 01 2000 | Grease gun with air bleed valve | |
7377406, | Apr 14 2005 | WEEMS INDUSTRIES, INC D B A LEGACY MANUFACTURING COMPANY; WEEMS INDUSTRIES, INC , D B A LEGACY MANUFACTURING | Two stage grease gun |
8297476, | Nov 10 2008 | WEEMS INDUSTRIES, INC D B A LEGACY MANUFACTURING COMPANY | Quick connect grease gun barrel and method of use |
9057482, | May 24 2012 | KING CHO MACHINERY INDUSTRIAL CO , LTD | Auto/single functions selecting device for grease gun and method for operating the same |
9062825, | Jun 26 2012 | Grease gun | |
9726322, | Oct 21 2014 | GREE-SEE TECHNOLOGY, LLC | Grease gun and cartridge unit |
20030183634, | |||
20050103808, | |||
20100116850, | |||
20100294808, | |||
20140061242, | |||
20150233524, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 16 2017 | SORG, DANIEL MARK | GREE-SEE TECHNOLOGY, LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 042178 | /0437 |
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